Chapter 10 THE KINGDOM ANIMALIA

Chapter 10 THE KINGDOM ANIMALIA In this chapter we trace the long evolutionary history of the animals; in it we encounter the simplest members of this kingdom sponges, jellyfish and several kinds of worms. These animals are important ecologically and they illustrate the advent of the major characteristics that are important in the more advanced animal phyla. These characteristics include the development of tissues and organs, the use of internal digestion, the appearance of radial and then bilateral body organization and the appearance of internal body cavities. DIVERSITY AND COMPLEXITY Animals, the members of this kingdom are the most conspicuous living organism in the world around us. As individuals, animals are greatly out numbered by plants, bacteria and even fungi. Yet there are more kinds of animals than any other type of organism. A total of about 1.3 million species of animals are included in this kingdom. It constitutes around 75% of the total known species of living organisms. An organism is a complete living being. Animals range in size and complexity from a merely microscopic parazoan Trichoplax to the giant blue whale Balaenopterathat reaches a length of nearly 40 meters and weighs more than 160,000 Kilograms (Fig. 10.1). Between these extremes is an immense diversity of animals that differs a great deal not only in size, appearance and habitat but also in having virtually no organs to a highly specialized organ system. The members of most of the phyla are found in shallow water or moist soil. True land dwelling forms are found in phylum Arthropoda and Chordata. Such a diversified group of animals is thought to had arisen from an ancestral colonial, probably volvox like protist (protoctist) as a result of division of labour among their aggregated cells. Some cells became specialized for movement, others for nutrition and still others differentiated into gametes. These coordinated groups of cells evolved into larger and more complex organisms that we now call animals. Multicellular animals have arisen from the protists at least three times. The sponges (phylum Porifera), cnidarians (phylum Cnidaria), and flat worms (phylum Platyhelminthes) probably represent the three separate evolutionary lines. The other animal phyla probably evolved from a flatworm or flatworm like ancestor. 10.1 ANIMAL CLASSIFICATION In order to better understand such a large number of organisms, it is necessary to arrange them in groups. This arrangement presents a great deal of information in an orderly way. In the traditional two-kingdom-system of classification (not followed these days) the multicellular animals were referred to as Metazoa to distinguish them from one-celled Protozoa. In modern five kingdom classification scheme, the Protozoa belongs to kingdom Protoctista whereas the true animals are placed in kingdom Animalia. A true animal is now defined as "a eukaryotic, multicellular, heterotrophic (ingestive mode of feeding) organisms which are diploid and developed from an embryo formed by the fusion of two different haploid gametes, a larger egg and a smaller sperm". Most of animals are motile, a few, however, are sessile. The kingdom Animalia is divided into 33 groups called phyla, out of which we will deal with only nine major ones. Each of these groups include a sufficient number of species and individuals which play an important role in an ecological community. These major phyla are Porifera, Cnidaria, Platyhelminthes, Book arranged by www.mynoteslibrary.com 112

Nemathelminthes, Annelida, Mollusca, Arthropoda, Echinodermata and Chordata (see chart No. 1). Rest of the groups are called minor phyla. This classification or grouping of animals is called Taxonomy or Systematics. It is carried out primarily on the basis of their evolutionary relationships. Clues to these relationships are found in (i) the comparative study of their morphology (general appearance) and (ii) their internal architecture which includes their cellular organization, symmetry and the embryological developmental pattern of their coelom and blastopore etc. The structure of DNA and the study of their comparative biochemistry and physiology also help in tracing their relationships. 10.1.1 Developmental Patterns: An animal starts its life as a zygote, which is a diploid cell, formed as a result of fertilization. It develops by a sequence of mitotic division, called cleavage, into a multicellular structure, first a solid ball of cells the morula and then a hollow ball of cells the blastula. In most of the animals the blastula invaginates i.e. foldsinwards, at a point to form gastrula, has a hollow sac having an opening called blastopore (Fig. 10.2). Further development and movement of cells produce a hollow digestive system called an enteron if it is open at one end only and a gut, if it has developed a second opening. The details of further embryonic development differ widely from phylum to phylum but are fairly constant within each phylum. Such developmental details provide very important criteria for determining relationship between the phyla. 10.1.2 Cellular Organization: Animal, phyla described in the next pages are in approximate order of increasing complexity. All the animals are multicellular and their cells are eukaryotic. These cells are joined together into tissues, tissues into organs and organs into organsystem. One phylum Porifera, is grouped in a separate sub-kingdom Parazoa because its members lack a proper tissue organization. Rest of the eight phyla constituting sub-kingdom Eumetazoa (True Metazoans) have tissues organized into organs (in the lower groups) and organs into organ systems (in higher forms). 10.1.3 Diploblastic and Triploblastic Organization: The process of gastrulation leads to the development of three tissue layers in almost all eumetazoa. These tissue layers, often called germ layers, are the masses of cell from which organ systems of animals develop. These germ layers called ectoderm, endoderm and mesoderm are the outer, inner and middle layers, respectively. In Porifera any such fully developed layer is lacking. In Cnidarians only two layers ectoderm and endoderm develop (Fig. 10.3) and they are called diploblastic. In the rest of the phyla, however, all the three germ layers are formed and hence they are called triploblastic animals (Fig. 10.4). 10.1.4 Symmetry: There are two branches of Eumetazoa. One consists of radially symmetrical organisms, the Coelenterata (Cnidaria) while the rest of all the phyla show bilateral symmetry. What is symmetry? Symmetry is the overall shape of an animal body. All the symmetrical animals can be divided, along at least one plane, into two identical halves. Animals that have no plane of symmetry are said to be asymmetrical e.g. sponges. A body with radial symmetry has one main axis around which body parts are arranged and the organism can be divided into identical halves by any plane that passes through the main axis. Cnidarians and Echinoderms are the examples of radially symmetrical animals. A bilaterally symmetrical animal can be divided into identical right and left halves only by a cut through the mid-line of its body (Fig. 10.5). Book arranged by www.mynoteslibrary.com 113

10.1.5 Coelom: The bilaterally symmetrical animal phyla may be divided into three groups:acoelomata (Platyhelminthes) are those which lack a body cavity; Pseudocoelomata (Nematodes) are those which develop a body cavity but lack a true coelom. The Coelomata (from Annelida to Chordata) are all those which develop a true coelom (Fig.10.6and chart No.1). In coelomates the meso-dermal layer splits open to contain a space that widens and eventually forms a body cavity in which digestive, reproductive and other organs develop and are suspended. This true body cavity, being lined by mesodermal layers, is called the coelom. A pseudocoelom is though a body cavity which also encloses the intestine but it is not formed by the splitting of mesoderm. Acoelomate animals have no such body cavity at all. 10.1.6 Fate of Blastopore: Blastopore is the opening which develops in an embryo at the gastrula stage. This opening eventually forms either the mouth or anus of the animal. 10.1.7 Protostomes and Deuterostomes: Coelomate animals are distinguished according to the fate of the blastopore into two groups, the Protostomata and Deuterostomata (see Fig. 10.2). In group Protostomata (Proto = First; Stoma=Mouth) the blastopore eventually becomes the mouth of adult whereas in group deuterostomata (Deutero = Second; Stoma = Mouth) the blastopore develops into anus and a second opening which develops later forms the mouth. Out of the major coelomate phyla annelida, mollusca and arthropoda are protostomates whereas echinodermata and chordata are deuterostomates. 10.2 PHYLUM PORIFERA (Pore Bearing) Phylum porifera which includes about 5,000 species are the simplest living animals usually called sponges. They are so called because they have thousands of pores called ostia or the incurrent pores through which water enters and one or few larger openings called oscula or excurrent pores through which water leaves the body. These pores are connected with a system of canals through which water flows. Sponges are usually asymmetrical, sessile, aquatic organisms. Most of them are marine whereas about 150 types live in fresh water. They lack mouth, intestine, respiratory, excretory and nervous systems. Oxygen diffuses in through the body wall and food is filtered out from water which flows through their body. Waste particles and fluids simply diffuse out of the body or flow out through oscula. A sponge may be described as an assemblage of loosely organized cells rather than a well defined multicellular organism. The pinacocytes are the contractile flattened cells forming the epidermis, porocytes form the pores whereas choanocytes are flagellated cells lining the inner hollow cavity the spongocoel (Fig. 10.7). The spongocoel may be a single cavity or divided and redivided into thousands of small chambers and canals thus increasing the surface area available. Three types (Fig. 10.8) i.e. Ascon type (spongocoel single cavity, not divided), Sycon type (spongocoel divided into secondary chambers) and Leucon type (spongocoel divided and redivided into secondary and tertiary chambers) of canal systems are found in sponges. Between pinacocytes and choanocytes is a gelatinous mesenchyme which consists of amoebocytes and spicules. Spicules which may be calcareous or siliceousconstitute the skeleton of sponges. The skeleton of bathroom sponges, however, is a network of spongin fibres. Many sponges look coloured due to symbiotic algae or due to the presence of pigments in amoebocytes. Book arranged by www.mynoteslibrary.com 114

A 10 cms sponge filters more than 20 litres of water everyday. Most sponges are hermaphrodite whereas in a few sexes are separate. During sexual reproduction eggs and sperms formed by amoebocytes. The sperms are carried out by water current to neighbouring sponges where fertilization takes place. The fertilized egg develops into a multicellular free swimming Amphiblastula larva which settles to the bottom and grows into an adult. Asexual reproduction takes place either by regeneration of fragments of sponges or by spore like Gemmule formation. Gemmules (Fig. 10.9) are actually nutrient laden amoeboid cells surround by layers of epithelial cells. Gemmule is resistant to drought or winter and when conditions become favourable it grows into a new sponge, Sycon (Fig. 10.10), Euplectella (Fig. 10.11) and Euspongia (Fig. 10.12) are the common examples of this phylum. Sponges, with a skeleton of spongin fibre network, are of commercial value being dried and used as bathroom sponges. Sponge fishing and sponge culture was very common in the past though in the recentyears it has been very much replaced by the artificial sponges. Three classes on the basis of skeleton are: i) Calcarea: Skeleton of needle shaped lime-crystals e.g. Ascon, Sycon. ii) iii) Hexactinellida: Spicules silicious (glass material) with six rays e.g. e.g. Euplectella. Demospongiae: Skeleton of proteinacious fibers (spongin fibers) either with or without spicules, e.g. Spongilla, etc. Spicules when present are siilceous but never six rayed. 10.3 PHYLUM CNIDARIA (With Nematocytes) Phylum Cnidaria which includes about 9000 species is also commonly called Coelenterata (with hollow enteron). This group of morphologically leastcomplex metazoa includes the common Hydras, Jelly fishes, Sea Anemones and the microscopic animals responsible for building coral reefs. Cnidarians are all aquatic, majority of them are marine whereas a few live in fresh water. They are radially symmetrical and diploblastic. Their body wall encloses a hollow cavity the gastro-vascular cavity or coelenteron, hence the name coelenterata (Fig. 10.13). Coelenteron which serves as a rudimentary gut opens to the exterior through just one opening which serves both as mouth and anus. The development of an enteron and a rudimentary network of nerves in cnidarians is the first evolutionary step towards formation of organ system. The cnidarians have no respiratory, excretory or circulatory system because all the cells of the body are close enough to the external medium so that respiration and excretion occur directly by diffusion through the cell membranes. All cnidarians are carnivorous. They paralyse or kill their prey with the help of special stinging cells called cnidocytes (Fig. 10.13), hence the name cnidaria. 10.3.1 Diploblastic Organization: Cnidarians are called diploblastic animals because their body wall is composed of two cellular layers, an outer ectoderm and an inner endoderm (Fig. 10.14). In between these two cellular layers is a plate of non-cellular gelatinous mass called mesogloea. The cellular layers in cnidarians are more complex than those in porifera and consist of cells whose activities are co-ordinated to form tissues. Thus cnidaria are considered to have evolved to tissue grade of organization but lack true organs. As a group cnidarians have two distinct body forms, Polyp and Medusa.Polypsare cylindrical with mouth and tentacles situated at the upper end. Medusae, on the other hand are umbrella shaped whose mouth and tentacles are Book arranged by www.mynoteslibrary.com 115

on the lower surface (Fig. 10.15). Hydra, Sea anemone and Corals occur only in polyp form being adapted to sessile life style whereas Jelly fish occurs only in medusa form and are adapted to a free-living, motile life style. 10.3.2 Alternation of Generation: Some cnidarians alternate between two body types during their life cycles. Inthese species the asexual polyp produces male or female medusae which as a result of sexual reproduction form zygote which transforms into a planula larva (Fig. 10.16-a) which eventually develops into a new asexual polyp. This phenomenon of producing asexual form by sexual form and vice versa is called Alternation of Generation (Fig. 10.16-b). 10.3.3 Polymorphism: Many cnidarians live as a part of a large colony in which many individuals become physically attached to one another and occur in many different forms or zooids. These zooids are interdependent and perform special function for whole of the colony. This ensures an efficient division of labour. It is a common feature of hydrozoan colonies. The occurrance of a species in two or more structurally and functionally different kind of zooids is known as Polymorphism. Physalia (Fig. 10.17) is a common example of a polymorphic colony in which many types of polypoid and medusoid forms live together, in a colony, and perform specific functions. 10.3.4 Corals and Coral reefs: Many polypoid cnidarians secrete certain chemicals which form a hard but dead protective covering around them. These coverings are of various shapes, sizes and chemical composition and are called corals. Coral reefs are underwater limestone ridges near the surface of the sea. These are usually formed by the combined secretions of several species of coelenterates and other carbon precipitating protoctist organisms. Coral reefs which are usually restricted to warm shallow waters provide a heaven to a large number of marine species. Great Barrier Reef of Australia's eastern coast is spread over hundred of miles. Jewellery and other decorative items are carved from the red corals. Red coral by the name of 'MARJAN' is used by Hakeems in preparing eastern medicines. 10.3.5 Phylogeny: Phylogenetically it is believed that the cnidarians have evolved along one of the three evolutionary lines from protoctista. No other phylum of animals is thought to have evolved from cnidaria. There are following three classes based upon the dominant phase. i) Hydrozoa: Mesoglea noncellular, both polypoid and medusoid phases showing alternation of generation e.g. Hydra, Obelia, Physalia (portuguese man of war). ii) iii) Scyphozoa: Mesoglea cellular; predominantly medusoid e.g. Aurelia (Jelly fish). Polyp occurs during development. Anthozoa: Mesoglea fibrous, polpoids forms only e.g corals, seaanemone. 10.4 PHYLUM PLATYHELMINTHES (Flat worms) There are found about 15000 species of Platyhelminthes. They are soft bodied flat or ribbon shaped worms thought to have evolved from a coelenterate like worm which resembled a planula larva. Of all the animals that have a head, platyhelminthes are the least complex. They have a mouth which opens into a gut but no anus. They are acoelomate, bilaterally symmetrical, triploblastic animals Book arranged by www.mynoteslibrary.com 116

with organs and organ systems. They have a much branched intestine and a network of excretory tubule with a large number of ciliated protonephridia. These moving cilia look like a flickering flame hence called flame cells. A rudimentary nervous system is also present whereas circulatory and respiratory systems are not needed hence absent. Flat worm are mostly hermaphrodite with complex life cycles which may include many larval stages. They are mostly external or internal parasites of animals to which they remain attached by their special adhesive organs, the hooks and suckers (Fig. 10.21). These parasitic flat worms complete their life cycle in one or two hosts hence called Monogenic, when one host is involved and Digenic, when two animal hosts are involved. Commonexamplesof Platyhelminthes are Dugesia (Planaria Fig. 10.21). Fasciola (Liver fluke Fig. 10.22) and Taenia saginata (Tape worm Fig. 10.23) 10.4.1 Parasitic Adaptations: Platyhelminthes have developed a number of adaptations which made them suitable for their parasitic mode of life. Their thick body covers protect them against defence mechanisms of host body. The spines, suckers and hooks developed for attachment and have replaced the locomotory organs which are not needed by parasitic animals. Alimentary canal is reduced, even absent as in Taenia, because of the availability of digested food from host. Neurosensory organs are not developed due to their passive mode of life; Reproductive, system is very much developed. In Taenia a set of reproductive organs is present in almost every segment. Fertility rate is very high to cope with chances of danger from the defence mechanism of the host body. It is worth while to be aware of parasitic worms because they cause diseases, multiply rapidly and are wide spread. Many are spread due to poor sanitary conditions. Hygienic living, careful inspection of edibles and thorough cooking of meat are the ways to avoid their infection. There are three classes in this phylum, according to their mode of living. i) Turbelaria (Turbella = A little sting): Free living, e.g.dugesia (Planaria). ii) iii) Trematoda(Trema = hole, cavity of sucker):ecto or endoparasites; alimentary canal bifurcated. e.g. Fasciola hepatica (sheep liver - fluke). Cestoda (Kestos = ribbon, eidos = like): Exclusively endo parasite; alimentary canal absent body ribbon shaped e.g. Taenia saginata (Beef tape - worm). 10.5 PHYLUM NEMATHELMINTHES-ASCHELMINTHES (The roundworms): Nemathelminthes commonly called round worms are the most wide spread and abundant animals on earth. Though about 20,000 species have been identified, incredible numbers of nematodes are found every where particularly in the soil. In one count90,000round worms of several different species were found within a single rotting apple. Nemathelminthes, which range in their size, from microscopic forms to a 9 meters length, have long bilaterally symmetrical, triploblastic and cylindrical bodies with pointed ends. They are basically constructed as a tube within a tube body plan. Inner tube is a relatively simple straight digestive tract with mouth and anus at opposite ends. Outer tube is a complex body wall being covered over by a non-living cuticle. Between the tubes is a fluid filled body cavity, the pseudocoel. Round worms have a varied mode of existence from free living scavengers to predators and parasitic on animals and even plants. At least 50 different species of round worms can inhabit the human body. Millions of human beings in the Book arranged by www.mynoteslibrary.com 117

world are infected with Ascaris (Fig. 10.24) alone. It is the most common human round worm and lives as an endoparasite in the intestine of man. They, like other nematodes, are sexually dimorphic, males being shorter than females. Enormous number of eggs are produced by females. Their eggs containing the developing embryo enter the human body with contaminated food or water. A female Ascaris may produce as many as 2,00,000 eggs every day. The thread worm like Wuchereria transmitted by blood sucking mosquitoes inhabit the lymphatic vessels of many animals including man where it produces a disease called Filariasis causing excessive inflammation of legs, arms and scrotum; a condition called Elephantiasis (Fig. 10.25). Another common nematode parasite Ancylostoma, the Hook worm whose larva can penetrate through the skin of man to reach the intestine where it matures and sucks the blood. 10.6 PHYLUM ANNELIDA (Segmented Worms) Annelida, commonly called segmented worms, have the most complex body structures of all the worms. They are distinguished by their ring like (Annulus: little ring) external segments. They look like a large number of rings put on and arranged one behind the other. These rings or external segments, called metameres, coincide with the internal partitions called septa of the body cavity. There are about 15000 species of annelida known. They are all triploblastic, bilaterally symmetrical coelomates with an organ system level of body organization. Their segmentation is said to be metameric because external segmentation corresponds with internal segmentation and some of their organs such as excretory and reproductive organs are repeated in each segment. Another important characteristic is the development of coelomic compartments in their body. Chitinous chaetae also called setae with or without parapodia are usually present in the most of annelids and help in locomotion whereas in some annelids suckers perform this function. The excretory organs are a pair or more, tubular nephridia per segment. Digestive, excretory, nervous and reproductive systems are well developed. Respiration takes place by diffusion through the moist skin. Annelida is the first group to have a circulatory system of closed type with definite blood vessels and many pulsatile hearts. Blood is usually red with haemoglobin dissolved in it. Annelids live on land, in moist soil, in fresh water or in sea. Many annelids are active free swimming predators, some are aquatic filter feeder living in tubes burried in mud whereas leeches are ectoparasites and suck the blood of their host. There are also many type of burrowing forms called the earthworms, which feed upon dead organic matter. Polychaetes, the most ancient annelids, are supposed to have evolved from a primitive flat worm like ancestor in the sea. Oligochaetes evolved from polychaetes whereas leeches evolved from oligochaetes. Phylum Annelida is divided into three classes mainly on the basis of number and type of setae. Class Polychaeta (With many setae): Polychaetes are usually free living active swimmers or sedentary filter feeding tubuculous forms. They are mostly marine having a pair oflateral flap like fleshy lobes the parapodia on each segment of the body. Each parapodium has a bundle of bristles called setae or chaetae. Sexes are usually separate. Development passes through a Trochophore larval stage. Common examples are Sabella (Peacock worm) and Nereis (Clam worm) (Fig. 10.26). Book arranged by www.mynoteslibrary.com 118

Class Oligochaeta (Few Setae): Oligochaeta are usually terrestrial, free living, burrowing forms withoutparapodia but with a few setae per segment arranged in a ring. All are hermaphrodite. Common example is Pheretima the common earthworm (Fig. 10.27). Class Hirudinea (Leeches): This group of annelids includes the leeches, in which setae and parapodia both are absent instead an anterior and a posterior suckers are present for blood sucking and attachment. Some are free living predator whereas others are ectoparasite of vertebrates and invertebrates. They live usually in fresh water and are all hermaphrodite. Common example is Hirudinaria (Fig. 10.28) the common Indian leech. A substance in a leech's saliva called hirudin prevents blood from clotting. 10.6.1 Advantages of Segmentation and Coelom: Segmentation increases flexibility allowing various parts of the body to bend independently of the other parts. Increased flexibility enhances locomotory power. The coelom improves swimming or burrowing activities of the annelids by serving as a hydrostatic skeleton. In many annelids coelom collects metabolic wastes discharged by excretory organs. It also provides space for maturation of eggs and sperms. 10.6.2 Importance: Earth-worms being farmer is friend, are one of the most beneficial animals for the mankind. They help the farmers by continuously ploughing the soil and adding nitrogenous wastes into it, thus making the soil more fertile. They are used by Chinese, Japanese and Indians in preparation of various fancy medicines. They are also used as fish bait, as food offish and also in laboratories for dissections and other research activities. Leeches are ectoparasites and suck the blood of their aquatic hosts. They are also used in remote areas, for sucking foul blood from a patient. A few are also carrier of some diseases. 10.7 PHYLUM MOLLUSCA (Soft Bodied) Molluscs are soft bodied animals; most have an external and some have an internal shell. About 50,000 species of living and 35,000 of fossil mollusca have so far been described making it the second largest phylum after Arthropoda. As a group mollusca underwent one of the most remarkable of animal evolutionary radiation in shape and also in size. The smallest molluscs are not bigger than the sand grain whereas the giant squids, the largest invertebrate known, may grow to meters long (including the tentacles) and 1800 Kg in weight. All the molluscs are triploblastic, coelomate. Bilaterally symmetrical animals with organ-system grade of body organization. They are mostly unsegmented. Though coelom has reduced to a few pockets the large fluid filled cavities of the open circulatory system become the major component of hydrostatic skeleton. Majority are provided with a rasping feeding structure, the radula in their buccal cavity. The alimentary canal is a straight or coiled tube, with a mouth and anus at the opposite ends. Excretory and nervous systems are also well developed. Respiration takes place by gills in aquatic form and by a rudimentary lung in terrestrial forms. Though molluscs have most varied body forms yet they share at least three common characters (Fig. 10.29). (i) Ahead-foot portion primarily concerned with sensation, feeding and locomotion. Book arranged by www.mynoteslibrary.com 119

(ii) (iii) A dorsal visceral mass that includes the major organs. A mantle, which is a fold of delicate tissue, surrounding the entire body. In most of the molluscs sexes are separate and fertilization takes place in water. They all pass through a trochophore larva stage. As the animals of phylum annelida also have a trochophore larval stage it is believed that segmented worms and molluscs are related. Although phylum mollusca is usually divided into six classes; Monoplacophora, Amphineura, Scaphopoda, Gastropoda, Bivalvia and Cephalopoda, only the last three classes will be discussed here. Class Gastropoda (Foot on visceral mass): This is the largest class of mollusca which includes whelks, snails and slugs. They are mostly marine, though some live in fresh water and still others are terrestrial. Many of them become, secondarily, asymmetrical by the twisting of visceral mass at 180 by a phenomenon called torsion. They have a prominent head and a broad muscular foot developed on the visceral mass. External shell may be present or absent, whenever present it is usually spirally coiled e.g. Pila (Fig. 10.30). Class Bivalvia (Shell with 2 halves): This group is the second largest class of phylum Mollusca. They are called Bivalvia because their bodies are enclosed in a shell which consists of a right and a left piece. These pieces called valves are movably hinged together. The muscular foot is ventral and laterally compressed suited for creeping and burrowing in the soft mud orsand. Bivalves are both marine and fresh water forms. Common examples of this class are Unio (Fig. 10.31 -a). Mytilus and Pearl Oysters (Fig. 10.31-b). Class Cephalopoda (Foot on the head): Cephalopods are all marine and exhibit a high degree of development. Foot in cephalopods is transformed into suckers bearing tentacles and arms. It is present in a ring around the mouth. Nautilus, Sepia (cuttle fish), Loligo (Squids) and Octopus (devil fish) are the common cephalopods. Nautilus (Fig. 10.32-a) has an external shell. Sepia (Fig. 10.32-b) and Loligo have developed an internal one whereas Octopus (Fig. 10.32-c) has none. Squids are the largest invertebrates. 10.7.1 Economic Importance: Since the earliest recorded time molluscs have been used by human beings. They are important in palaentological studies and as index fossils to underlying oil deposits. A variety of molluscs called shell fish, together with crustaceans, are still an important source of food. Their shells are decorative and their inner lustrous layer which is a mixture of calcium carbonate and proteins is called Necre or mother of pearl. In some bivalve molluscs, called Pearl Oyster, concentric layer of necre are deposited around any foreign particle that comes to lie between the mantle and the shell. This particle transforms into the most beautiful and precious jewellery item, the pearl. Pearl culture industry is being successfully run in Japan and China by artificially introducing the fragment of man made particles, of a variety of shapes, in pearl oysters. 10.8 PHYLUM ARTHROPODA (Jointed legs) Arthropoda is the largest phylum of the animal kingdom, and includes about one million species. They are found everywhere on the earth wherever the life is possible, even in the oil wells. Arthropods are bilaterally symmetrical, triploblastic Book arranged by www.mynoteslibrary.com 120

and metamerically segmented animals. The bodies of the most of arthropods are divided into a head, a thorax and an abdomen. Coelomic space in arthropoda is called haemocoel because it is occupied by blood sinuses of the open circulatory system. Respiration takes place through gills in aquatic forms, by tracheae in insects and by book-lungs in scorpions. Alimentary canal is well developed and assisted by jaws. Excretory organs are mostly malpighian tubules. Nervous system is developed and of annelidan type. Compound eyes with mosaic vision is also a factor of advantage in arthropods. Sexes are usually separate and metamorphosis is of common occurrence. 10.8.1 Metamorphosis: It is a set of changes which transforms a larva into its developed adult form. A larva is a creature which in some animals, comes out of the egg in an immature and undeveloped stage. Metamorphosis is said to be complete when a larva hatches out of the egg and develops into a resting stage the pupa which in turn transforms into an adult. Incomplete metamorphosis, on the other hand is that in which a tiny, immature but adult like creature called nymph comes out of the egg and grows directly, into an adult. 10.8.2 Advantages of exoskeleton, jointed appendages and wings: A significant advancement in this group is their jointed appendages, hence the name Arthropoda. These appendages serve many functions which include walking, swimming, food capture, copulation and sensory perceptions. Another important features of Arthropoda is their exoskeleton which covers, externally, whole of the body and appendages. This exoskeleton is water proof and made tip of chitin. It is non-living and as the animal outgrows it is shed and a new one is formed. This mechanism of regular changing over of exoskeleton and formation of the new one is called Moulting or Ecdysis. The evolution of exoskeleton and jointed legs are the most important features which made the distribution of arthropods that much diversified so as to make them the most successful group of animals. Exoskeleton not only protects the body organs but also provides sites for muscle attachment which together with the advantage of developed jointed appendages resulted in efficient swimming in water and running on land. Further more the development of wings made possible their invasion into the atmosphere (Fig. 10.33). Arthropoda has the largest kinds of animals but Nematoda has the largest number. About 80% of the animal species are arthropods and 90% of the arthropods are insects. 10.8.3 Economics Importance: Arthropods are of great economic importance. The predominant group of arthropoda, the insects, not only helps in pollination but also predates on plant pest. Many cause diseases, in plant and animals, by transmitting bacteria and viruses. In human beings they are responsible for the transmission of Trypanosoma,Plasmodium and germs of cholera etc. Arthropods are an important source of food for many animals and carnivorous plants. Sea food, that is not fish or mollusc, is generally arthropods. Farming of honey bees called apiculture and those of silk worms called sericulture are being carried out at a large scale and are of great economic importance to mankind. Phylum Arthropoda is divided into following five classes. Book arranged by www.mynoteslibrary.com 121

Class Merostomata (mouth plates): It is a small group of marine arthropods in which mouth is surrounded by many small plates. It includes Limulus (Pig. 10.34) the King Crab which is considered a living fossil. Class Arachnida (spider like): It is a group of terrestrial arthropods with four pairs of walking legs. They respire by the help of book lungs, tracheae or general body surface. The most well known examples are scorpions (Fig. 10.35-a). They are comparatively large and possess a sting at the end of their narrow segmented posterior abdomen. The largest number of species of arachnids are spiders (Fig. 10.35-b). They are predators. They possess silk glands which secrete a protein that on exposure to air forms silk threads used in building nest and webs for trapping the preys. Class Crustacea (with carpaee): Prawns, shrimps, lobsters, crabs and many other arthropods belong to this class. They are marine, fresh water and even terrestrial creatures. Crustaceans possess two pairs of antennae, a pair of mandibles and two pairs of maxillae around their mouth. The body is divided into head, thorax and abdomen. In many cases, e.g. prawn (Fig. 10.36-a) (Fig, 10.36-b), head and thorax become fused to form cephalothoraxwhich is covered over by a single plate of exoskeleton called carapace. Their appendages are modified for walking, swimming, feeding, respiration and as accessory respiratory structures. There are usually five pairs of walking legs. Majority of crustaceans are free living whereas a few e.g. Sacculina are parasite. Daphnia and cyclops are the common microscopic fresh water forms. Economically important crustaceans being used as food are prawns, shrimps and lobsters. Class Myriapoda (many legs): These are terrestrial arthropods leading a hidden life in the soil. Their body consists of a head and a very long trunk consisting of many similar segments. The head bears a pair of antennae and trunk is provided with paired lateral appendages. This class includes Centipedes (Fig. 10.37-a) with one pair and Millipede (Fig. 10.37-b) with two pairs of appendages per segment. Class Insecta or Hexapoda (six legs): This is the largest class of the animal kingdom. It includes more than 90% of the arthropod species. Members of this large group are called insects and their study is called entomology. Insect body is divided into head, thorax and abdomen. This class is also called Hexapoda because they possess on their thorax three pairs of walking legs. They are found in all types of habitats but majority are terrestrial. The success of insects can partly be attributed to the development of flight. In flying insects one or two pairs of wings develop dorsally on thorax. The group of insects with wings is called Pterygota whereas the group without wings is called Apterygota. A pair of antennae on head is also a characteristic of insects. Insects have developed many types of specialized mouth parts to suit their mode of feeding. They may be biting and chewing type as in cockroach, piercing and sucking type as in mosquito, chewing and lapping type as in honey bee, sponging type as in house fly and siphoning type as in butter fly. They mostly lead an independent life; a few ants, termites and honey bees live in large colonies, with a marked division of labour, and are called social insects. Flies and mosquitoes (Fig. 10.38-a) are involved in transmission of many diseases e.g cholera, dysentery and malaria. Fleas are ectoparasite on many warm blooded animals whereas rat fleas are involved in the transmission of a deadly human disease the Plague. Grasshoppers, moths, butter flies and beetles are Book arranged by www.mynoteslibrary.com 122

regarded as pest of plants. Cockroaches (Fig. 10.38-b) are very common in warm damp places including our kitchens and bath rooms whereas silver fish (Fig. 10.38-c), actually an insect, is found in the book shelves. 10.8.4 Insects a successful group: Insects are found everywhere in the world from low land upto the tops of Himalaya and from hot springs to Antaratican temp: of 65 C. They are even found in the oil wells. This great diversity of habitats has become possible due to various structural and physiological modifications and social adaptations the insects have undergone. Structural modifications include developed brain and sense organs, developed mouth parts in accordance with the requirements of food available, a protective exoskeleton, development of wings and jointed appendages. Physiological modifications include the production of a variety of digestive enzymes, high reproductive potential and metamorphosis which have collectively increased their chances of survival even in the extreme environments. As social insects, they live in a co-ordinated society which increases the adaptability to the environment and enhances the chances of their survival. 10.9 PHYLUM ECHINODERMATA (Spiny Skinned) Echinodermata is a group of about 6000 species of exclusively marine animals. They begin their lives as free swimming bilaterally symmetrical larvae but as adults they have radially symmetrical bodies. As the bodies of most of the echinoderms have five symmetrically radiating parts or arms they are referred to as Pentaradial (Pentamerous). None of the Echinoderms lives out of the sea. Adult echinoderms though lack head, brain and segmentation; are triploblastic, coelomate deuterostomes with organ-system grade of body organization. The body is covered over by a delicate epidermis stretched over a firm endoskeleton of fixed or movable calcareous plates with spines. These spines, which are present all over the body may be long as in Sea Urchin or short as in sand dollars. These spines are the characteristic of this group and inspired the name Echinodermata. The calcareous plates covering the body are perforated over certain areas through which special organs the tube feet project out. These thousands of tube feet are a part of a unique water vascular system (Fig. 10.39) which is also a characteristic of echinodermata. These tube feet serve for locomotion, holding of food and respiration. Most echinoderms exhibit the remarkable power to regenerate their lost parts. Reproduction is usually sexual. In some cases, however, it is asexual. Development is indirect passing usually through a bipinnaria larval stage. Common echinoderms are star fish (Fig. 10.40), brittlestar (Fig. 10.41), sea cucumber (Fig. 10.42) and sea urchin (Fig. 10.43). 10.9.1 Affinities: Affinities mean similarities of characters suggesting relationship. Echinoderms are thought to be the relative of chordates and hemichordates on the basis of the embryological similarities like their style of cleavage, pattern of blastulation and gastrulation and the deuterostomy of the blastopore. The tornaria larva of hemichordata and bipinnaria larva of echinodermata has a large number of morphological, biochemical and anatomical resemblances. In fact the tornaria larva when first discovered was mistaken as an echinoderm. These affinities have led to the conclusion that echinoderms evolved as a side branch from a common Dipleura like ancestor which also gave rise to hemichordata and chordata. Book arranged by www.mynoteslibrary.com 123

HEMICHORDATA (Half Notochord): Phylum Hemichordata is a small group of animals which includes about 90 species. They are all soft bodied animals which usually live in shallow 'U' shaped burrows in the sandy or muddy sea bottom. These cylinderical or vase shaped animals are bilaterally symmetrical and lack any segmentation. They may be solitary or colonial and usually range between a few millimetre and 250 centimetres in length. Balanoglossus gigas, however, may reach a length of 1.5 meters. Their circulatory system is open and coelom is divided into three chambers. A dorsal and a ventral nerve cord are present being connected together by transverse rings. Sexes are separate in hemichordate though no sexual dimorphism is seen. As the blastopore of the embryo develops into anus hemichordates are deuterostomes. Embryological studies of tornaria larva of hemichordata, however, reveal a close and fundamental resemblance with bipinnaria larva of echinodermata. Hence, it is believed that echiondermata, hemichordata and chordata are closely related and might have evolved from a common ancestor. 10.10 PHYLUM CHORDATA (Forms with notochord) Members of this phylum, are the best known of all the animals. They include about45000species including many animals of major economic importance. All the chordates show all or at least any one of the following three fundamental characters (Fig. 10-44). 1. Notochord: It is a flexible cartilagineous skeletal rod which forms in the early stage in the embryos of all the chordates in the mid-dorsal line, dorsal to the gut but ventral to the nerve cord. It extends the length of the body and persists in a few chordates, throughout their life whereas in most of them it is surrounded and replaced by a vertebral column. 2. Hollow, dorsal, tubular nerve cord: In all the chordates a hollow, tubular, fluid filled, nerve cord always develop in the mid-dorsal line. In the group craniata it becomes differentiated into brain and spinal cord. 3. Pharyngeal gill slits: In all the chordates, in an early embryonic stage, walls of pharynx become perforated. In aquatic forms these pharyngeal slits develop gills whereas in terrestrial forms they close and disappear. Chordates, in general, are bilaterally symmetrical, triploblastic, deuterostome, animals having a complete digestive tract with a mouth and an anus. Coelom is well developed and internal organs are suspended in the coelomic cavity by a thin membranous tissue called mesentery. They all, as a rule, reproduce sexually. A majority have a post-anal tail. According to the recent classification Phylum Chordata is divided into two groups (i) Acraniata or Protochordata and (ii) Craniata or Vertebrata. Group: Acraniata or Protochordata (First chordates; without brain box): Protochordates or Acraniates as their name indicates are the first or simple chordates in which brain box (Cranium) is absent and hence brain is not prominent. In this group of chordates notochord does not transform into vertebral Book arranged by www.mynoteslibrary.com 124

column. Protochordata or Acraniata is divided into two sub phyla Urochordata and Cephalochordata. Sub-phylum: Urochordata (Notochord in the Tail) Urochordates are also called Tunicata because their body is enclosed in a sac called Tunic. They are all marine and mostly sessile. The tunic is provided with two openings, an incurrentor buccalsiphon and an excurrent or Atrial siphon. It is through these openings that water currents bring food and oxygen and take away the excretory wastes and gametes. An adult Ascidia (Fig. 10.45) shows little chordate characters. It is actually its motile larva, which resembles a tadpole, and exhibits chordate characters. It contains a nerve cord and a short notochord in its tail only, hence the name Urochordata. As the larva reaches maturity it attaches to the sea bottom and undergoes retrogressive metamorphosis by losing its tail and most of the chordate characters. Many species of Herdmania are found in our seas. Sub-Phylum: Cephalochordata (Notochord from head to tail) This is a small group and includes Branchiostomawhich is commonly called Amphioxus (Fig. 10.46). It is a small marine animal with its both ends pointed. It lives burried in sand in shallow water with its anterior end protruded out. Though a small animal it is a typical chordate and exhibits, quite clearly, all the fundamental chordate characters i.e. a hollow dorsal nerve cord, a number of pharyngeal gills slits and a notochord which extends right in the mid dorsal line from anterior to posterior tip of the body. Out of only two genera found around the world Branchiostoma is found on our coasts. Group: Craniata or Vertebrata (With cranium and vertebral column): These are the chordates in which brain is protected inside a skeletal brain box called cranium. They are also called vertebrates because in the members of this group notochord is replaced by a vertebral column. This group is divided into two sub-phyla (i) Agnatha and (ii) Gnathostomata. Sub-Phylum: Agnatha (Mouth with out jaws): This is a small group of vertebrates which includes only one class Cyclostomata hence Agnatha are also commonly called cyclostomes. As the members of this group superficially resemble the fishes but lack the jaw they are often known as Jawless Fishes. This group includes Hag Fish and Lamprey (Fig. 10.47-a.b). They are elongated eel like animals without jaws, scales or paired fins. They have a rounded suctorial mouth with many rings of teeth. Both are parasites. Sub-Phylum: Gnathostomata (Mouth with Jaws) This is a large group of vertebrates in which both upper and lower jaws are present though teeth may be present or absent. Gnathostomata are divided into two super classes Pisces and Tetrapoda. As more than half of the chordates are fishes hence they are in grouped is a super class called pisces. Super Class Pisces (Fish): Thisis the largest group of chordates which includes about25000 species of fishes. Study of fishes is called lchthyology. A fish is an aquatic gill breathing gnathostomates whose streamlined body is provided with paired fins and covered over by dermal scales. Super class Pisces is divided into two classes: (i) Chondrichthyes and (ii) Osteichthyes. Book arranged by www.mynoteslibrary.com 125

Class Chondrichthyes (Cartilagineous fishes): This group also called class Elasmobranchi comprises of marine fishes whose endoskeleton is made up of cartilages while their skin contain an enormous number of tiny sharp enamel coated denticles called placoidscales(fig. 10.48) which form their exoskeleton. Their wide mouth is ventral in position and their tail fin is heterocercal. There are present many usually 5 exposed gill slits on each side which are not covered over by a gill cover the operculum. This group includes sharks (Fig. 10.49-a), skates and rays including shock producing Electric ray-torpedo (Fig. 10.49-b). Many types of skates and rays are found on our coasts. Scoliodon called Dog fish is a small shark which is common in our seas. Class Osteichthyes (Bony Fishes): This group also called Teleostomi is actually the largest class of chordates. They are marine and fresh water fishes in which mouth openning is present at the anterior tip. The endoskeleton in these fishes is bony and the exoskeleton which is made up of thin bony plates which are called cycloid (Fig. 10.50-a) or ctenoid (Fig. 10.50-b) scales according to whether their outer edge is smooth or spiny. The gills are covered over on each side, by a gill cover called operculum. Most of these fishes have an air bladder which acts as a hydrostatic organ. Tail fin is usually homocercal or diphycercal. This group includes Eel (Fig. 10.51-a), Sea horse (Fig. 10.51-b), Flying fish (Fig. 10.51-c), Globe fish (Fig. 10.51-d) etc. Most of the delicious edible fishes also belong to this group. The commonly liked edible fishes of Pakistan (Fig.10.52) are Perches (Pomfret), Hilsa (Pallah), Carps (Rohu), Mackrels (Surmai), Cat fishes (Khagga), and Salmon (Trout). Some fishes travel thousands of kilometres to their spawing areas. A small group of zoogeographically important fishes called Lung fishes (Fig. 10.53) belonging to order Dipnoiare also included in the Class Osteichthyes. Only three genera of such fishes are found in the world. They respire by the help of gill as well as, at times during drought period; by lungs which are actually the modified air bladders. They are found isolated, one type each in South America, Africa and Australia hence called American lung fish, African lung fish and Australian lung fish respectively. 10.10.1 Adaptations for an Aquatic life: The fishes are well adapted to aquatic life due to their streamlined body shape, which is helpful in swimming, by the presence of paired and unpaired fins and tail for balance and propulsion, by losing hard armour and developing air bladder for bouncy and by developing the gills for aquatic respiration. To overcome the deficiency of sense of hearing and sight in water their sense of smell has developed remarkably. Super class Tetrapoda (Four legs): This is the group of vertebrates which have developed two pairs of pentadactyl limbs for walking, running, flying or for offence and defence. This group of Gnathostomates is divided into 4 classes (i) Amphibia (ii) Reptilia (iii) Aves and (iv) Mammalia. Class Amphibia (Living at both places; water and land): This is a comparatively small group of tetrapod comprising of about 2000 species. This is the only group of vertebrates which lacks any sort of exoskeleton. Hence their naked skin is soft and moist. They respire by lungs, gills, skin and lining of buccal cavity. They lay eggs in water where they spend at least their early life. Hence, they have become partially aquatic and partially terrestrial. Their name amphibia also indicates this double mode of life. Book arranged by www.mynoteslibrary.com 126